Two large thin conducting plates with a small gap in between are placed in a uniform electric field E (perpendicular to the plates.)The area of each plate is A, and charges `+Q and -Q` are given to these plates as shown in figure. If R,S, and T are three points in space, then the

Two large parallel conducting plates of net charge 2Q and -Q are placed in a uniform external electric field (Q)/(2Aepsilon_(0)) prependicular to plates as shown. The surface area of each plates is A. The charge on the left surface of the left plate and right surface of the right plate are respectively.

Two large parallel conducting plates of net charge 2Q and -Q are placed in a uniform external electric field (Q)/(2Aepsilon_(0)) prependicular to plates as shown. The surface area of each plates is A. The charge on the left surface of the left plate and right surface of the right plate are respectively.

Two large conducting plates of a parallel plate capacitor are given charges Q and 3Q respectively. If the electric field in the region between the plates is E_0 , then the force of interaction between the plates is

Two large conducting plates of a parallel plate capacitor are given charges Q and 3Q respectively. If the electric field in the region between the plates is E_0 , then the force of interaction between the plates is

A parallel plate capacitor has a uniform electric field vec(E) in the space between the plates. If the distance between the plates is 'd' and the area of each plate is 'A' the energy stored in the capacitor is

A parallel plate capacitor has a uniform electric field E in the space between the the plates. If the distance between the plates is d and area of each plate is A, the energy stored in the capacitor is

A parallel plate capacitor has a uniform electric field E in the space between the the plates. If the distance between the plates is d and area of each plate is A, the energy stored in the capacitor is